1. A Mechanical Feedback Restricts Sepal Growth and Shape in Arabidopsis
Nathan Hervieux, Mathilde Dumond, Aleksandra Sapala, Anne-Lise Routier-Kierzkowska, Daniel Kierzkowski, Adrienne H.K. Roeder, Richard S. Smith, Arezki Boudaoud, Olivier Hamant 
Current Biology 
Volume 26, Issue 8, Pages (April 2016)
DOI: /j.cub
Copyright © 2016 Elsevier Ltd Terms and Conditions

2. Figure 1
Growth Analysis for a Time-Lapse Series of an Abaxial Sepal Growing for 168 Hr
The white arrow shows the apicobasal axis of the sepal (the tip of the arrow corresponds to the distal tip of the sepal) for all images.
(A) Heatmap of areal expansion (%) over consecutive 24-hr intervals, displayed on the second time point (see also Figure S1). The developmental stage of the flower was assigned at each time point as in [22]. Each time point is displayed from the side (left) and from the top (right). The same magnification is used for all stages. Note that averaged growth data are represented: averaging is a similar approach to the Tauriello displacement field [21] and has a similar effect, i.e., smoothing out the noise to identify underlying trends.
(B and C) Images of selected time points from the image sequence displayed in (A).
(B) Anisotropy of growth calculated as deformation in maximal growth direction (PDGmax; PDG, principal direction of growth) divided by deformation in minimal growth direction (PDGmin). White bars represent the direction of maximal growth for cells displaying growth anisotropy above 20%.
(C) Cell proliferation over 24 hr displayed for selected time points.
Color scales indicate the number of daughter cells that arose from a single cell within the previous 24 hr. Scale bars, 50 μm. See also Figure S1.
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3. Figure 2
A Stereotypical Growth and Cortical Microtubule Pattern Prescribed a Mechanical Stress Pattern at the Tip
(A, D, and G) CMT organization at the surface of the abaxial sepal (see also Figure S2). The direction and length of the red bars indicate the average orientation and anisotropy of CMTs in each cell, respectively.
(B, E, and H) Heatmap of areal expansion (%) over 24-hr intervals displayed on the first time point. PDGs are indicated in white for expansion and in red for shrinkage.
(C, F, I, and J) Details of CMT organization in regions highlighted with a white symbol in (A), (D), and (G).
(K) Heatmap of the anisotropy of CMT arrays presented in (G).
(L and M) Mechanical simulation of a growing sepal (successive time points), without any mechanical feedback. Areal growth rates (L) as well as stress direction and magnitude (M) are represented.
Scale bars, 20 μm. Scale is identical for all time points in the simulation. See also Figure S2.
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4. Figure 3 CMTs Align along Maximal Tensile Stress in Growing Sepals
(A–I) Compression of the abaxial sepal results in the reversible apparent bundling of CMTs. A white asterisk is added to help in the observation of the cell lineage in the different time points.
(A, D, and G) Live imaging of an abaxial sepal before (A) and after compression (D and G).
(B, E, and H) Close-up of the CMT apparent bundling response in the compressed domain.
(C, F, and I) Close-up of CMT behavior in the uncompressed domain (control).
(J–N) Effect of oryzalin treatment on CMT orientation and growth pattern.
(J and L) Live imaging of an abaxial sepal after oryzalin treatment.
(K and M) Heatmap of areal expansion (%) over 24-hr intervals displayed on the first time point. PDGs are indicated with expansion in white and shrinkage in red.
(N) Close-up of the tip of an abaxial sepal 48 hr after oryzalin treatment showing a supracellular CMT alignment at the tip.
Scale bars, 20 μm. See also Figure S3.
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5. Figure 4 A Mechanical Feedback May Channel Sepal Shape
(A–C) Mechanical simulation of a growing sepal, with a weak mechanical feedback on growth direction (s = 6, αM = 2). The areal growth rate (A), stress direction and magnitude (B), and resulting mechanical anisotropy (C) are represented. The scale is identical for all time points.
(D–F) Mechanical simulation of a growing sepal, with a moderate mechanical feedback on growth direction (s = 20, αM = 2). The areal growth rate (D), stress direction and magnitude (E), and resulting mechanical anisotropy (F) are represented. The scale is identical for all time points.
(G–I) Mechanical simulation of a growing sepal, with a strong mechanical feedback on growth direction (s = 20, αM = 3.5). The areal growth rate (G), stress direction and magnitude (H), and resulting mechanical anisotropy (I) are represented. The scale is identical for all time points.
(J–L) Live imaging of the CMT response after mechanical ablation in different genotypes.
(J) Ablation induces a circumferential orientation of microtubule arrays around the site of ablation in the WT.
(K) The CMT response to ablation is slower in the botero1-7 mutant.
(L) The CMT response to ablation occurs earlier in the spiral2-2 mutant: a full CMT reorientation was visible as early as 3 hr after ablation.
The direction and length of the red bars indicate the average orientation and anisotropy of CMTs in each cell, respectively. Asterisks indicate the ablation sites. Scale bars, 20 μm.
(M) Mature sepals in the wild-type (Col-0) and botero1-7 and spiral2-2 mutants. Scale bar, 1 mm.
(N) Close-up of the tip of mature sepals in the corresponding genotype. Scale bar, 0.5 mm.
See also Figure S4.
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